blob: 8631a52a5ced973583f76cfc086fde270366f0c6 [file] [log] [blame]
/*
* Copyright 2018-2020 NXP
* All rights reserved.
*
*
* SPDX-License-Identifier: BSD-3-Clause
*/
#ifndef __SERIAL_MANAGER_H__
#define __SERIAL_MANAGER_H__
/*!
* @addtogroup serialmanager
* @{
*/
/*******************************************************************************
* Definitions
******************************************************************************/
/*! @brief Enable or disable serial manager non-blocking mode (1 - enable, 0 - disable) */
#ifdef DEBUG_CONSOLE_TRANSFER_NON_BLOCKING
#ifndef SERIAL_MANAGER_NON_BLOCKING_MODE
#define SERIAL_MANAGER_NON_BLOCKING_MODE (1U)
#endif
#else
#ifndef SERIAL_MANAGER_NON_BLOCKING_MODE
#define SERIAL_MANAGER_NON_BLOCKING_MODE (0U)
#endif
#endif
/*! @brief Enable or disable uart port (1 - enable, 0 - disable) */
#ifndef SERIAL_PORT_TYPE_UART
#define SERIAL_PORT_TYPE_UART (0U)
#endif
/*! @brief Enable or disable USB CDC port (1 - enable, 0 - disable) */
#ifndef SERIAL_PORT_TYPE_USBCDC
#define SERIAL_PORT_TYPE_USBCDC (0U)
#endif
/*! @brief Enable or disable SWO port (1 - enable, 0 - disable) */
#ifndef SERIAL_PORT_TYPE_SWO
#define SERIAL_PORT_TYPE_SWO (0U)
#endif
/*! @brief Enable or disable USB CDC virtual port (1 - enable, 0 - disable) */
#ifndef SERIAL_PORT_TYPE_USBCDC_VIRTUAL
#define SERIAL_PORT_TYPE_USBCDC_VIRTUAL (0U)
#endif
/*! @brief Set serial manager write handle size */
#if (defined(SERIAL_MANAGER_NON_BLOCKING_MODE) && (SERIAL_MANAGER_NON_BLOCKING_MODE > 0U))
#define SERIAL_MANAGER_WRITE_HANDLE_SIZE (44U)
#define SERIAL_MANAGER_READ_HANDLE_SIZE (44U)
#else
#define SERIAL_MANAGER_WRITE_HANDLE_SIZE (4U)
#define SERIAL_MANAGER_READ_HANDLE_SIZE (4U)
#endif
#if (defined(SERIAL_PORT_TYPE_UART) && (SERIAL_PORT_TYPE_UART > 0U))
#include "serial_port_uart.h"
#endif
#if (defined(SERIAL_PORT_TYPE_USBCDC) && (SERIAL_PORT_TYPE_USBCDC > 0U))
#if !(defined(SERIAL_MANAGER_NON_BLOCKING_MODE) && (SERIAL_MANAGER_NON_BLOCKING_MODE > 0U))
#error The serial manager blocking mode cannot be supported for USB CDC.
#endif
#include "serial_port_usb.h"
#endif
#if (defined(SERIAL_PORT_TYPE_SWO) && (SERIAL_PORT_TYPE_SWO > 0U))
#include "serial_port_swo.h"
#endif
#if (defined(SERIAL_PORT_TYPE_USBCDC_VIRTUAL) && (SERIAL_PORT_TYPE_USBCDC_VIRTUAL > 0U))
#if !(defined(SERIAL_MANAGER_NON_BLOCKING_MODE) && (SERIAL_MANAGER_NON_BLOCKING_MODE > 0U))
#error The serial manager blocking mode cannot be supported for USB CDC.
#endif
#include "serial_port_usb_virtual.h"
#endif
#define SERIAL_MANAGER_HANDLE_SIZE_TEMP 0U
#if (defined(SERIAL_PORT_TYPE_UART) && (SERIAL_PORT_TYPE_UART > 0U))
#if (SERIAL_PORT_UART_HANDLE_SIZE > SERIAL_MANAGER_HANDLE_SIZE_TEMP)
#undef SERIAL_MANAGER_HANDLE_SIZE_TEMP
#define SERIAL_MANAGER_HANDLE_SIZE_TEMP SERIAL_PORT_UART_HANDLE_SIZE
#endif
#endif
#if (defined(SERIAL_PORT_TYPE_USBCDC) && (SERIAL_PORT_TYPE_USBCDC > 0U))
#if (SERIAL_PORT_USB_CDC_HANDLE_SIZE > SERIAL_MANAGER_HANDLE_SIZE_TEMP)
#undef SERIAL_MANAGER_HANDLE_SIZE_TEMP
#define SERIAL_MANAGER_HANDLE_SIZE_TEMP SERIAL_PORT_USB_CDC_HANDLE_SIZE
#endif
#endif
#if (defined(SERIAL_PORT_TYPE_SWO) && (SERIAL_PORT_TYPE_SWO > 0U))
#if (SERIAL_PORT_SWO_HANDLE_SIZE > SERIAL_MANAGER_HANDLE_SIZE_TEMP)
#undef SERIAL_MANAGER_HANDLE_SIZE_TEMP
#define SERIAL_MANAGER_HANDLE_SIZE_TEMP SERIAL_PORT_SWO_HANDLE_SIZE
#endif
#endif
#if (defined(SERIAL_PORT_TYPE_USBCDC_VIRTUAL) && (SERIAL_PORT_TYPE_USBCDC_VIRTUAL > 0U))
#if (SERIAL_PORT_USB_VIRTUAL_HANDLE_SIZE > SERIAL_MANAGER_HANDLE_SIZE_TEMP)
#undef SERIAL_MANAGER_HANDLE_SIZE_TEMP
#define SERIAL_MANAGER_HANDLE_SIZE_TEMP SERIAL_PORT_USB_VIRTUAL_HANDLE_SIZE
#endif
#endif
/*! @brief SERIAL_PORT_UART_HANDLE_SIZE/SERIAL_PORT_USB_CDC_HANDLE_SIZE + serial manager dedicated size */
#if ((defined(SERIAL_MANAGER_HANDLE_SIZE_TEMP) && (SERIAL_MANAGER_HANDLE_SIZE_TEMP > 0U)))
#else
#error SERIAL_PORT_TYPE_UART, SERIAL_PORT_TYPE_USBCDC, SERIAL_PORT_TYPE_SWO and SERIAL_PORT_TYPE_USBCDC_VIRTUAL should not be cleared at same time.
#endif
/*! @brief Definition of serial manager handle size. */
#if (defined(SERIAL_MANAGER_NON_BLOCKING_MODE) && (SERIAL_MANAGER_NON_BLOCKING_MODE > 0U))
#define SERIAL_MANAGER_HANDLE_SIZE (SERIAL_MANAGER_HANDLE_SIZE_TEMP + 120U)
#else
#define SERIAL_MANAGER_HANDLE_SIZE (SERIAL_MANAGER_HANDLE_SIZE_TEMP + 12U)
#endif
/*!
* @brief Defines the serial manager handle
*
* This macro is used to define a 4 byte aligned serial manager handle.
* Then use "(serial_handle_t)name" to get the serial manager handle.
*
* The macro should be global and could be optional. You could also define serial manager handle by yourself.
*
* This is an example,
* @code
* SERIAL_MANAGER_HANDLE_DEFINE(serialManagerHandle);
* @endcode
*
* @param name The name string of the serial manager handle.
*/
#define SERIAL_MANAGER_HANDLE_DEFINE(name) \
uint32_t name[((SERIAL_MANAGER_HANDLE_SIZE + sizeof(uint32_t) - 1U) / sizeof(uint32_t))]
/*!
* @brief Defines the serial manager write handle
*
* This macro is used to define a 4 byte aligned serial manager write handle.
* Then use "(serial_write_handle_t)name" to get the serial manager write handle.
*
* The macro should be global and could be optional. You could also define serial manager write handle by yourself.
*
* This is an example,
* @code
* SERIAL_MANAGER_WRITE_HANDLE_DEFINE(serialManagerwriteHandle);
* @endcode
*
* @param name The name string of the serial manager write handle.
*/
#define SERIAL_MANAGER_WRITE_HANDLE_DEFINE(name) \
uint32_t name[((SERIAL_MANAGER_WRITE_HANDLE_SIZE + sizeof(uint32_t) - 1U) / sizeof(uint32_t))]
/*!
* @brief Defines the serial manager read handle
*
* This macro is used to define a 4 byte aligned serial manager read handle.
* Then use "(serial_read_handle_t)name" to get the serial manager read handle.
*
* The macro should be global and could be optional. You could also define serial manager read handle by yourself.
*
* This is an example,
* @code
* SERIAL_MANAGER_READ_HANDLE_DEFINE(serialManagerReadHandle);
* @endcode
*
* @param name The name string of the serial manager read handle.
*/
#define SERIAL_MANAGER_READ_HANDLE_DEFINE(name) \
uint32_t name[((SERIAL_MANAGER_READ_HANDLE_SIZE + sizeof(uint32_t) - 1U) / sizeof(uint32_t))]
/*! @brief Macro to determine whether use common task. */
#ifndef SERIAL_MANAGER_USE_COMMON_TASK
#define SERIAL_MANAGER_USE_COMMON_TASK (1U)
#endif
/*! @brief Macro to set serial manager task priority. */
#ifndef SERIAL_MANAGER_TASK_PRIORITY
#define SERIAL_MANAGER_TASK_PRIORITY (2U)
#endif
/*! @brief Macro to set serial manager task stack size. */
#ifndef SERIAL_MANAGER_TASK_STACK_SIZE
#define SERIAL_MANAGER_TASK_STACK_SIZE (1000U)
#endif
/*! @brief The handle of the serial manager module */
typedef void *serial_handle_t;
/*! @brief The write handle of the serial manager module */
typedef void *serial_write_handle_t;
/*! @brief The read handle of the serial manager module */
typedef void *serial_read_handle_t;
/*! @brief serial port type*/
typedef enum _serial_port_type
{
kSerialPort_Uart = 1U, /*!< Serial port UART */
kSerialPort_UsbCdc, /*!< Serial port USB CDC */
kSerialPort_Swo, /*!< Serial port SWO */
kSerialPort_UsbCdcVirtual, /*!< Serial port USB CDC Virtual */
} serial_port_type_t;
/*! @brief serial manager config structure*/
typedef struct _serial_manager_config
{
#if defined(DEBUG_CONSOLE_TRANSFER_NON_BLOCKING)
uint8_t *ringBuffer; /*!< Ring buffer address, it is used to buffer data received by the hardware.
Besides, the memory space cannot be free during the lifetime of the serial
manager module. */
uint32_t ringBufferSize; /*!< The size of the ring buffer */
#endif
serial_port_type_t type; /*!< Serial port type */
void *portConfig; /*!< Serial port configuration */
} serial_manager_config_t;
/*! @brief serial manager error code*/
typedef enum _serial_manager_status
{
kStatus_SerialManager_Success = kStatus_Success, /*!< Success */
kStatus_SerialManager_Error = MAKE_STATUS(kStatusGroup_SERIALMANAGER, 1), /*!< Failed */
kStatus_SerialManager_Busy = MAKE_STATUS(kStatusGroup_SERIALMANAGER, 2), /*!< Busy */
kStatus_SerialManager_Notify = MAKE_STATUS(kStatusGroup_SERIALMANAGER, 3), /*!< Ring buffer is not empty */
kStatus_SerialManager_Canceled =
MAKE_STATUS(kStatusGroup_SERIALMANAGER, 4), /*!< the non-blocking request is canceled */
kStatus_SerialManager_HandleConflict = MAKE_STATUS(kStatusGroup_SERIALMANAGER, 5), /*!< The handle is opened */
kStatus_SerialManager_RingBufferOverflow =
MAKE_STATUS(kStatusGroup_SERIALMANAGER, 6), /*!< The ring buffer is overflowed */
kStatus_SerialManager_NotConnected = MAKE_STATUS(kStatusGroup_SERIALMANAGER, 7), /*!< The host is not connected */
} serial_manager_status_t;
/*! @brief Callback message structure */
typedef struct _serial_manager_callback_message
{
uint8_t *buffer; /*!< Transferred buffer */
uint32_t length; /*!< Transferred data length */
} serial_manager_callback_message_t;
/*! @brief callback function */
typedef void (*serial_manager_callback_t)(void *callbackParam,
serial_manager_callback_message_t *message,
serial_manager_status_t status);
/*******************************************************************************
* API
******************************************************************************/
#if defined(__cplusplus)
extern "C" {
#endif /* _cplusplus */
/*!
* @brief Initializes a serial manager module with the serial manager handle and the user configuration structure.
*
* This function configures the Serial Manager module with user-defined settings.
* The user can configure the configuration structure.
* The parameter serialHandle is a pointer to point to a memory space of size #SERIAL_MANAGER_HANDLE_SIZE
* allocated by the caller.
* The Serial Manager module supports three types of serial port, UART (includes UART, USART, LPSCI, LPUART, etc), USB
* CDC and swo.
* Please refer to #serial_port_type_t for serial port setting.
* These three types can be set by using #serial_manager_config_t.
*
* Example below shows how to use this API to configure the Serial Manager.
* For UART,
* @code
* #define SERIAL_MANAGER_RING_BUFFER_SIZE (256U)
* static SERIAL_MANAGER_HANDLE_DEFINE(s_serialHandle);
* static uint8_t s_ringBuffer[SERIAL_MANAGER_RING_BUFFER_SIZE];
*
* serial_manager_config_t config;
* serial_port_uart_config_t uartConfig;
* config.type = kSerialPort_Uart;
* config.ringBuffer = &s_ringBuffer[0];
* config.ringBufferSize = SERIAL_MANAGER_RING_BUFFER_SIZE;
* uartConfig.instance = 0;
* uartConfig.clockRate = 24000000;
* uartConfig.baudRate = 115200;
* uartConfig.parityMode = kSerialManager_UartParityDisabled;
* uartConfig.stopBitCount = kSerialManager_UartOneStopBit;
* uartConfig.enableRx = 1;
* uartConfig.enableTx = 1;
* config.portConfig = &uartConfig;
* SerialManager_Init((serial_handle_t)s_serialHandle, &config);
* @endcode
* For USB CDC,
* @code
* #define SERIAL_MANAGER_RING_BUFFER_SIZE (256U)
* static SERIAL_MANAGER_HANDLE_DEFINE(s_serialHandle);
* static uint8_t s_ringBuffer[SERIAL_MANAGER_RING_BUFFER_SIZE];
*
* serial_manager_config_t config;
* serial_port_usb_cdc_config_t usbCdcConfig;
* config.type = kSerialPort_UsbCdc;
* config.ringBuffer = &s_ringBuffer[0];
* config.ringBufferSize = SERIAL_MANAGER_RING_BUFFER_SIZE;
* usbCdcConfig.controllerIndex = kSerialManager_UsbControllerKhci0;
* config.portConfig = &usbCdcConfig;
* SerialManager_Init((serial_handle_t)s_serialHandle, &config);
* @endcode
*
* @param serialHandle Pointer to point to a memory space of size #SERIAL_MANAGER_HANDLE_SIZE allocated by the caller.
* The handle should be 4 byte aligned, because unaligned access doesn't be supported on some devices.
* You can define the handle in the following two ways:
* #SERIAL_MANAGER_HANDLE_DEFINE(serialHandle);
* or
* uint32_t serialHandle[((SERIAL_MANAGER_HANDLE_SIZE + sizeof(uint32_t) - 1U) / sizeof(uint32_t))];
* @param config Pointer to user-defined configuration structure.
* @retval kStatus_SerialManager_Error An error occurred.
* @retval kStatus_SerialManager_Success The Serial Manager module initialization succeed.
*/
serial_manager_status_t SerialManager_Init(serial_handle_t serialHandle, serial_manager_config_t *config);
/*!
* @brief De-initializes the serial manager module instance.
*
* This function de-initializes the serial manager module instance. If the opened writing or
* reading handle is not closed, the function will return kStatus_SerialManager_Busy.
*
* @param serialHandle The serial manager module handle pointer.
* @retval kStatus_SerialManager_Success The serial manager de-initialization succeed.
* @retval kStatus_SerialManager_Busy Opened reading or writing handle is not closed.
*/
serial_manager_status_t SerialManager_Deinit(serial_handle_t serialHandle);
/*!
* @brief Opens a writing handle for the serial manager module.
*
* This function Opens a writing handle for the serial manager module. If the serial manager needs to
* be used in different tasks, the task should open a dedicated write handle for itself by calling
* #SerialManager_OpenWriteHandle. Since there can only one buffer for transmission for the writing
* handle at the same time, multiple writing handles need to be opened when the multiple transmission
* is needed for a task.
*
* @param serialHandle The serial manager module handle pointer.
* The handle should be 4 byte aligned, because unaligned access doesn't be supported on some devices.
* @param writeHandle The serial manager module writing handle pointer.
* The handle should be 4 byte aligned, because unaligned access doesn't be supported on some devices.
* You can define the handle in the following two ways:
* #SERIAL_MANAGER_WRITE_HANDLE_DEFINE(writeHandle);
* or
* uint32_t writeHandle[((SERIAL_MANAGER_WRITE_HANDLE_SIZE + sizeof(uint32_t) - 1U) / sizeof(uint32_t))];
* @retval kStatus_SerialManager_Error An error occurred.
* @retval kStatus_SerialManager_HandleConflict The writing handle was opened.
* @retval kStatus_SerialManager_Success The writing handle is opened.
*
* Example below shows how to use this API to write data.
* For task 1,
* @code
* static SERIAL_MANAGER_WRITE_HANDLE_DEFINE(s_serialWriteHandle1);
* static uint8_t s_nonBlockingWelcome1[] = "This is non-blocking writing log for task1!\r\n";
* SerialManager_OpenWriteHandle((serial_handle_t)serialHandle, (serial_write_handle_t)s_serialWriteHandle1);
* SerialManager_InstallTxCallback((serial_write_handle_t)s_serialWriteHandle1,
* Task1_SerialManagerTxCallback,
* s_serialWriteHandle1);
* SerialManager_WriteNonBlocking((serial_write_handle_t)s_serialWriteHandle1,
* s_nonBlockingWelcome1,
* sizeof(s_nonBlockingWelcome1) - 1U);
* @endcode
* For task 2,
* @code
* static SERIAL_MANAGER_WRITE_HANDLE_DEFINE(s_serialWriteHandle2);
* static uint8_t s_nonBlockingWelcome2[] = "This is non-blocking writing log for task2!\r\n";
* SerialManager_OpenWriteHandle((serial_handle_t)serialHandle, (serial_write_handle_t)s_serialWriteHandle2);
* SerialManager_InstallTxCallback((serial_write_handle_t)s_serialWriteHandle2,
* Task2_SerialManagerTxCallback,
* s_serialWriteHandle2);
* SerialManager_WriteNonBlocking((serial_write_handle_t)s_serialWriteHandle2,
* s_nonBlockingWelcome2,
* sizeof(s_nonBlockingWelcome2) - 1U);
* @endcode
*/
serial_manager_status_t SerialManager_OpenWriteHandle(serial_handle_t serialHandle, serial_write_handle_t writeHandle);
/*!
* @brief Closes a writing handle for the serial manager module.
*
* This function Closes a writing handle for the serial manager module.
*
* @param writeHandle The serial manager module writing handle pointer.
* @retval kStatus_SerialManager_Success The writing handle is closed.
*/
serial_manager_status_t SerialManager_CloseWriteHandle(serial_write_handle_t writeHandle);
/*!
* @brief Opens a reading handle for the serial manager module.
*
* This function Opens a reading handle for the serial manager module. The reading handle can not be
* opened multiple at the same time. The error code kStatus_SerialManager_Busy would be returned when
* the previous reading handle is not closed. And there can only be one buffer for receiving for the
* reading handle at the same time.
*
* @param serialHandle The serial manager module handle pointer.
* The handle should be 4 byte aligned, because unaligned access doesn't be supported on some devices.
* @param readHandle The serial manager module reading handle pointer.
* The handle should be 4 byte aligned, because unaligned access doesn't be supported on some devices.
* You can define the handle in the following two ways:
* #SERIAL_MANAGER_READ_HANDLE_DEFINE(readHandle);
* or
* uint32_t readHandle[((SERIAL_MANAGER_READ_HANDLE_SIZE + sizeof(uint32_t) - 1U) / sizeof(uint32_t))];
* @retval kStatus_SerialManager_Error An error occurred.
* @retval kStatus_SerialManager_Success The reading handle is opened.
* @retval kStatus_SerialManager_Busy Previous reading handle is not closed.
*
* Example below shows how to use this API to read data.
* @code
* static SERIAL_MANAGER_READ_HANDLE_DEFINE(s_serialReadHandle);
* SerialManager_OpenReadHandle((serial_handle_t)serialHandle, (serial_read_handle_t)s_serialReadHandle);
* static uint8_t s_nonBlockingBuffer[64];
* SerialManager_InstallRxCallback((serial_read_handle_t)s_serialReadHandle,
* APP_SerialManagerRxCallback,
* s_serialReadHandle);
* SerialManager_ReadNonBlocking((serial_read_handle_t)s_serialReadHandle,
* s_nonBlockingBuffer,
* sizeof(s_nonBlockingBuffer));
* @endcode
*/
serial_manager_status_t SerialManager_OpenReadHandle(serial_handle_t serialHandle, serial_read_handle_t readHandle);
/*!
* @brief Closes a reading for the serial manager module.
*
* This function Closes a reading for the serial manager module.
*
* @param readHandle The serial manager module reading handle pointer.
* @retval kStatus_SerialManager_Success The reading handle is closed.
*/
serial_manager_status_t SerialManager_CloseReadHandle(serial_read_handle_t readHandle);
/*!
* @brief Transmits data with the blocking mode.
*
* This is a blocking function, which polls the sending queue, waits for the sending queue to be empty.
* This function sends data using an interrupt method. The interrupt of the hardware could not be disabled.
* And There can only one buffer for transmission for the writing handle at the same time.
*
* @note The function #SerialManager_WriteBlocking and the function SerialManager_WriteNonBlocking
* cannot be used at the same time.
* And, the function SerialManager_CancelWriting cannot be used to abort the transmission of this function.
*
* @param writeHandle The serial manager module handle pointer.
* @param buffer Start address of the data to write.
* @param length Length of the data to write.
* @retval kStatus_SerialManager_Success Successfully sent all data.
* @retval kStatus_SerialManager_Busy Previous transmission still not finished; data not all sent yet.
* @retval kStatus_SerialManager_Error An error occurred.
*/
serial_manager_status_t SerialManager_WriteBlocking(serial_write_handle_t writeHandle,
uint8_t *buffer,
uint32_t length);
/*!
* @brief Reads data with the blocking mode.
*
* This is a blocking function, which polls the receiving buffer, waits for the receiving buffer to be full.
* This function receives data using an interrupt method. The interrupt of the hardware could not be disabled.
* And There can only one buffer for receiving for the reading handle at the same time.
*
* @note The function #SerialManager_ReadBlocking and the function SerialManager_ReadNonBlocking
* cannot be used at the same time.
* And, the function SerialManager_CancelReading cannot be used to abort the transmission of this function.
*
* @param readHandle The serial manager module handle pointer.
* @param buffer Start address of the data to store the received data.
* @param length The length of the data to be received.
* @retval kStatus_SerialManager_Success Successfully received all data.
* @retval kStatus_SerialManager_Busy Previous transmission still not finished; data not all received yet.
* @retval kStatus_SerialManager_Error An error occurred.
*/
serial_manager_status_t SerialManager_ReadBlocking(serial_read_handle_t readHandle, uint8_t *buffer, uint32_t length);
#if (defined(SERIAL_MANAGER_NON_BLOCKING_MODE) && (SERIAL_MANAGER_NON_BLOCKING_MODE > 0U))
/*!
* @brief Transmits data with the non-blocking mode.
*
* This is a non-blocking function, which returns directly without waiting for all data to be sent.
* When all data is sent, the module notifies the upper layer through a TX callback function and passes
* the status parameter @ref kStatus_SerialManager_Success.
* This function sends data using an interrupt method. The interrupt of the hardware could not be disabled.
* And There can only one buffer for transmission for the writing handle at the same time.
*
* @note The function #SerialManager_WriteBlocking and the function #SerialManager_WriteNonBlocking
* cannot be used at the same time. And, the TX callback is mandatory before the function could be used.
*
* @param writeHandle The serial manager module handle pointer.
* @param buffer Start address of the data to write.
* @param length Length of the data to write.
* @retval kStatus_SerialManager_Success Successfully sent all data.
* @retval kStatus_SerialManager_Busy Previous transmission still not finished; data not all sent yet.
* @retval kStatus_SerialManager_Error An error occurred.
*/
serial_manager_status_t SerialManager_WriteNonBlocking(serial_write_handle_t writeHandle,
uint8_t *buffer,
uint32_t length);
/*!
* @brief Reads data with the non-blocking mode.
*
* This is a non-blocking function, which returns directly without waiting for all data to be received.
* When all data is received, the module driver notifies the upper layer
* through a RX callback function and passes the status parameter @ref kStatus_SerialManager_Success.
* This function receives data using an interrupt method. The interrupt of the hardware could not be disabled.
* And There can only one buffer for receiving for the reading handle at the same time.
*
* @note The function #SerialManager_ReadBlocking and the function #SerialManager_ReadNonBlocking
* cannot be used at the same time. And, the RX callback is mandatory before the function could be used.
*
* @param readHandle The serial manager module handle pointer.
* @param buffer Start address of the data to store the received data.
* @param length The length of the data to be received.
* @retval kStatus_SerialManager_Success Successfully received all data.
* @retval kStatus_SerialManager_Busy Previous transmission still not finished; data not all received yet.
* @retval kStatus_SerialManager_Error An error occurred.
*/
serial_manager_status_t SerialManager_ReadNonBlocking(serial_read_handle_t readHandle,
uint8_t *buffer,
uint32_t length);
/*!
* @brief Tries to read data.
*
* The function tries to read data from internal ring buffer. If the ring buffer is not empty, the data will be
* copied from ring buffer to up layer buffer. The copied length is the minimum of the ring buffer and up layer length.
* After the data is copied, the actual data length is passed by the parameter length.
* And There can only one buffer for receiving for the reading handle at the same time.
*
* @param readHandle The serial manager module handle pointer.
* @param buffer Start address of the data to store the received data.
* @param length The length of the data to be received.
* @param receivedLength Length received from the ring buffer directly.
* @retval kStatus_SerialManager_Success Successfully received all data.
* @retval kStatus_SerialManager_Busy Previous transmission still not finished; data not all received yet.
* @retval kStatus_SerialManager_Error An error occurred.
*/
serial_manager_status_t SerialManager_TryRead(serial_read_handle_t readHandle,
uint8_t *buffer,
uint32_t length,
uint32_t *receivedLength);
/*!
* @brief Cancels unfinished send transmission.
*
* The function cancels unfinished send transmission. When the transfer is canceled, the module notifies the upper layer
* through a TX callback function and passes the status parameter @ref kStatus_SerialManager_Canceled.
*
* @note The function #SerialManager_CancelWriting cannot be used to abort the transmission of
* the function #SerialManager_WriteBlocking.
*
* @param writeHandle The serial manager module handle pointer.
* @retval kStatus_SerialManager_Success Get successfully abort the sending.
* @retval kStatus_SerialManager_Error An error occurred.
*/
serial_manager_status_t SerialManager_CancelWriting(serial_write_handle_t writeHandle);
/*!
* @brief Cancels unfinished receive transmission.
*
* The function cancels unfinished receive transmission. When the transfer is canceled, the module notifies the upper
* layer
* through a RX callback function and passes the status parameter @ref kStatus_SerialManager_Canceled.
*
* @note The function #SerialManager_CancelReading cannot be used to abort the transmission of
* the function #SerialManager_ReadBlocking.
*
* @param readHandle The serial manager module handle pointer.
* @retval kStatus_SerialManager_Success Get successfully abort the receiving.
* @retval kStatus_SerialManager_Error An error occurred.
*/
serial_manager_status_t SerialManager_CancelReading(serial_read_handle_t readHandle);
/*!
* @brief Installs a TX callback and callback parameter.
*
* This function is used to install the TX callback and callback parameter for the serial manager module.
* When any status of TX transmission changed, the driver will notify the upper layer by the installed callback
* function. And the status is also passed as status parameter when the callback is called.
*
* @param writeHandle The serial manager module handle pointer.
* @param callback The callback function.
* @param callbackParam The parameter of the callback function.
* @retval kStatus_SerialManager_Success Successfully install the callback.
*/
serial_manager_status_t SerialManager_InstallTxCallback(serial_write_handle_t writeHandle,
serial_manager_callback_t callback,
void *callbackParam);
/*!
* @brief Installs a RX callback and callback parameter.
*
* This function is used to install the RX callback and callback parameter for the serial manager module.
* When any status of RX transmission changed, the driver will notify the upper layer by the installed callback
* function. And the status is also passed as status parameter when the callback is called.
*
* @param readHandle The serial manager module handle pointer.
* @param callback The callback function.
* @param callbackParam The parameter of the callback function.
* @retval kStatus_SerialManager_Success Successfully install the callback.
*/
serial_manager_status_t SerialManager_InstallRxCallback(serial_read_handle_t readHandle,
serial_manager_callback_t callback,
void *callbackParam);
#endif
/*!
* @brief Prepares to enter low power consumption.
*
* This function is used to prepare to enter low power consumption.
*
* @param serialHandle The serial manager module handle pointer.
* @retval kStatus_SerialManager_Success Successful operation.
*/
serial_manager_status_t SerialManager_EnterLowpower(serial_handle_t serialHandle);
/*!
* @brief Restores from low power consumption.
*
* This function is used to restore from low power consumption.
*
* @param serialHandle The serial manager module handle pointer.
* @retval kStatus_SerialManager_Success Successful operation.
*/
serial_manager_status_t SerialManager_ExitLowpower(serial_handle_t serialHandle);
#if defined(__cplusplus)
}
#endif
/*! @} */
#endif /* __SERIAL_MANAGER_H__ */